WO2019154286A1

WO2019154286A1 - Data modulation and demodulation method and apparatus

Info

Publication number: WO2019154286A1
Application number: PCT/CN2019/074267
Authority: WO
Inventors: 王磊; 张蕾; 吴艺群; 陈雁
Original assignee: 华为技术有限公司
Priority date: 2018-02-12
Filing date: 2019-01-31
Publication date: 2019-08-15
Also published as: CN110166163B; EP3745619B1; US20200374059A1; CN110166163A; EP3745619A1; EP3745619A4; US11201705B2

Abstract

Disclosed are a data modulation and demodulation method and apparatus. The method comprises: a terminal device divides data to be sent into N bit groups; the terminal device generates N complex symbol groups, wherein the ith complex symbol group is obtained by processing the ith bit group by using a mapping rule corresponding to the ith bit group, the mapping rule corresponding to the ith bit group is determined according to the group identifier of the ith bit group and a first parameter, and the first parameter comprises at least one of a pilot parameter, a hopping identifier, a terminal device identifier, the layer number of a non-orthogonal layer, and a hopping offset; and the terminal device sends the N complex symbol groups. Because the first parameters corresponding to different terminal devices are different, a set of mapping rules used by the different terminal devices are not identical, thus implementing interference between randomized terminal devices and improving the demodulation success rate of a network device.

Description

Data modulation and demodulation method and device

In this application, the priority of the Chinese Patent Application entitled "A Data Modulation and Demodulation Method and Apparatus" is filed on Dec. 12, 2018, the Chinese Patent Application No. 201101147021.4, the entire contents of which are incorporated by reference. In this application.

Technical field

The present application relates to the field of wireless communication technologies, and in particular, to a data modulation and demodulation method and apparatus.

Background technique

5G is a popular standard for next-generation cellular communication networks, covering enhanced mobile broadband (eMBB), ultra-reliable and low latency communication (uRLLC) and large-scale inter-machine communication (ulltra reliable & low latency communication (uRLLC)) Massive machine type of communication, mMTC) These three scenarios. Among them, the eMBB scene emphasizes high throughput, the uRLLC scene emphasizes high reliability and low latency, and the mMTC scene emphasizes the number of massive connections.

In the uRLLC scenario, multiple terminal devices are allowed to transmit simultaneously on the same resource because a lower transmission delay is required, where the same resource may be the same time domain resource, frequency domain resource, or code domain resource. Similarly, in the mMTC scenario, since it is necessary to support a large number of users at the same time, it is also necessary to allow a plurality of terminal devices to transmit on the same resource. The manner in which such multiple terminal devices share transmissions on the same resource is referred to as non-orthogonal transmission.

There are already many non-orthogonal transmission technologies, such as sparse coded multiple access (SCMA), multi-user shared access (MUSA), and pattern division multiple access (pattern). Division multiple access (PDMA), interleave grid multiple access (IGMA), resource spread multiple access (RSMA), etc.

In a non-orthogonal transmission system, in order to enable a network device to distinguish signals transmitted by multiple terminal devices on the same resource, signals transmitted by different terminal devices are generated by using different mapping rules. However, due to the limited mapping rules, especially in the scenario where multiple terminal devices are connected, multiple terminal devices may use the same mapping rule to generate signals, which may result in degradation of decoding and detection performance of the network device.

For example, the mapping rules of the SCMA technology are implemented by a codebook to implement mapping of data bits to complex symbol groups. Due to the limited mapping rules corresponding to the codebook, the codebook used by the terminal device will collide.

The mapping rules of the PDMA technology are embodied by a codebook to implement mapping of complex symbols to complex symbol groups. Due to the limited mapping rules corresponding to the codebook, the codebook used by the terminal device may collide.

The mapping rules of the MUSA technology are embodied by a spreading sequence. The complex symbol of each terminal device selects a spreading sequence from the set of spreading sequences, and the spread complex symbols are transmitted on the same time-frequency resource to implement mapping of the complex symbols to the complex symbol group. The network device separates each terminal device by an effective interference cancellation method. When there are many access terminal devices, the number of spreading sequences is limited for a given spreading factor (SF), and the spreading sequence used by the terminal device collides.

The mapping rules of the IGMA technology are embodied by the interleaving process. The data to be transmitted may be data obtained after bit-level interleaving processing. The complex symbol of each terminal device is subjected to interleaving processing, and the complex symbol group after the interleaving process is transmitted on the same time-frequency resource to implement mapping of the complex symbol to the complex symbol group. IGMA is also a non-orthogonal transmission method with sparse spread spectrum. For a given SF, the available interleaving pattern is also limited. When there are more access terminals, the interlace pattern will collide.

For non-orthogonal transmission, the mapping rule corresponding to the smaller spreading length is still very limited, especially the mapping rule with good correlation and can assist the network device to better demodulate is limited in a certain SF length. Therefore, in a multi-user access scenario, when there are many terminal devices, the codebooks, sequences, or interleaving patterns used by each user may have certain collisions and overlaps, which reduces the performance of decoding and detection at the receiving end. The above non-orthogonal multiple access (NOMA) techniques are described by taking a mapping rule of one bit group/one complex symbol group as an example for N bit groups/N complex symbol groups. The mapping rules are the same, that is, the mapping rules adopted also have the above problems.

Summary of the invention

The embodiment of the present invention provides a data modulation and demodulation method and device, which are used to solve the problem that multiple terminal devices in the prior art use the same mapping rule to generate signals, resulting in degradation of decoding and detection performance of the network device. problem.

In a first aspect, an embodiment of the present application provides a data modulation method, where the method includes:

The terminal device divides the data to be transmitted into N groups of bits, N≥2 and N is an integer; the terminal device generates N complex symbol groups, wherein the i-th complex symbol group adopts a mapping corresponding to the i-th bit group. The rule is obtained by processing the ith bit group, and the mapping rule corresponding to the ith bit group is determined according to the group identifier of the ith bit group and the first parameter, where the first parameter includes At least one of a pilot parameter, a hopping identifier, a terminal device identifier, a layer sequence number of a non-orthogonal layer, and a hopping offset; the mapping rules corresponding to the N bit groups respectively include at least two different from each other Mapping rule, 0 ≤ i ≤ N-1 and i is an integer; the terminal device transmits the N complex symbol groups.

Through the foregoing method, the terminal device divides the data to be transmitted into N groups of bits, and then processes the group of bits by using a mapping rule corresponding to each group of bits to generate N complex symbol groups, wherein each bitmap corresponds to a mapping group. The rule is determined according to the group identifier of the bit group and the first parameter. Because the first parameters of different terminal devices are different, a set of mapping rules adopted by different terminal devices will not be identical, thereby realizing interference between randomized terminal devices and solving similar or identical mappings of multiple terminal devices. The rule generation signal causes the network device to fail to decode, and improves the success rate of network device demodulation.

In a possible design, the data to be transmitted is data obtained by at least one of error correction coding, bit level interleaving, or bit level scrambling. The data to be transmitted may be composed of one or more coding blocks or a part of one coding block.

In a possible design, the mapping rule corresponding to the i-th bit group is determined according to the group identifier, the first parameter, and the second parameter of the i-th bit group, where the second parameter includes At least one of a cell identifier, a time domain resource sequence number, and a period P.

Through the above method, the mapping rule corresponding to each bit group can be determined by using a combination of various parameters.

In a possible design, when the terminal device repeatedly transmits the data to be transmitted, the mapping rule corresponding to the N bit groups is corresponding to the N bit groups at the time of the first transmission. The mapping rules are the same.

In a possible design, the mapping rule corresponding to the i-th bit group is the same as the mapping rule corresponding to the j-th bit group, where i=j+nP, P≥2, 0≤j<P,n ≥ 0, j, n, and P are integers. Or j=i mod P, P≥2, 0≤j<P, j, P are integers.

Through the above method, the terminal device can process the N bit groups with fewer mapping rules to obtain N complex symbol groups.

In one possible design, the terminal device is identified as a radio network temporary identifier RNTI, or a radio resource control RRC flag, or a temporary mobile subscriber identity number TMSI.

In a possible design, before the terminal device sends the N complex symbol groups, the terminal device performs scrambling processing on the N complex symbol groups, where the sum is used in the scrambling process. The scrambling sequence is determined according to at least one of the first parameter, the time domain resource sequence number, and the cell identifier;

In this case, the sending, by the terminal device, the N complex symbol groups is: the terminal device sends the signal after the N complex symbol groups are scrambled.

Through the above method, different terminal devices use different scrambling sequences for scrambling the complex symbol group.

In a possible design, before the terminal device sends the N complex symbol groups, the terminal device performs interleaving processing on the N complex symbol groups, where the interleaving pattern used in the interleaving process is Determining according to at least one of the first parameter, the time domain resource sequence number, and the cell identifier;

In this case, the sending, by the terminal device, the N complex symbol groups is: the terminal device sends a signal after the N complex symbol groups are interleaved.

Through the above method, the interleaving patterns used by the different terminal devices for interleaving the complex symbol groups are different.

In a second aspect, an embodiment of the present application provides a data demodulation method, where the method includes:

The network device receives the uplink signal; the network device determines a mapping rule corresponding to the N complex symbol groups in the uplink signal, where N≥2 and N is an integer; the network device respectively corresponds to the N complex symbol groups The mapping rule demodulates the corresponding complex symbol group; wherein the mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier of the i-th complex symbol group and the first parameter, the first parameter At least one of a pilot parameter, a hopping identifier, a terminal device identifier, a layer sequence number of a non-orthogonal layer, and a hopping offset, where the mapping rules corresponding to the N complex symbol groups respectively include at least two mutual Different mapping rules, 0 ≤ i ≤ N-1 and i is an integer.

Through the above method, the mapping rule corresponding to each bit group is determined according to the group identifier of the bit group and the first parameter. Because the first parameters of different terminal devices are different, a set of mapping rules adopted by different terminal devices will not be identical, thereby realizing interference between randomized terminal devices and solving similar or identical mappings of multiple terminal devices. The rule generation signal causes the network device to fail to decode, and improves the success rate of network device demodulation.

In a possible design, the mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier of the i-th complex symbol group, the first parameter and the second parameter, and the second The parameter includes at least one of a cell identifier, a time domain resource sequence number, and a period P.

In a possible design, when the network device determines that the N complex symbol groups are not first transmitted, the network device determines a mapping rule corresponding to the N complex symbol groups and the N complex symbol groups The mapping rules corresponding to the N complex symbol groups are respectively the same when the first transmission is performed.

In a possible design, the network device determines a mapping rule corresponding to the N complex symbol groups in the uplink signal, which may be, but is not limited to, the following methods:

Determining, by the network device, a pilot parameter corresponding to the pilot according to a pilot in the uplink signal, where the network device is configured according to the pilot parameter and each of the N complex symbol groups The identifier determines a mapping rule corresponding to each of the N complex symbol groups.

Determining, by the network device, the hopping identifier according to a pilot in the uplink signal; the network device determining, according to the hopping identifier and a group identifier of each of the plurality of N complex symbol groups Mapping rules corresponding to N complex symbol groups.

Determining, by the network device, the terminal device identifier according to the pilot in the uplink signal; the network device determining, according to the terminal device identifier and a group identifier of each of the plurality of N complex symbol groups Mapping rules corresponding to N complex symbol groups.

Therefore, the network device determines mapping rules corresponding to the N complex symbol groups according to the pilot and pilot parameters in the uplink signal, or the relationship between the pilot and the hopping identifier, or the pilot and the terminal device identifier.

Determining, by the network device, a layer sequence number of the M non-orthogonal layers, where M is a positive integer; the network device determining, in the N complex symbols, at least corresponding to each of the M non-orthogonal layers a complex symbol group, wherein the mth non-orthogonal layer corresponds to s _m complex symbol groups,

The mth non-orthogonal layer is any one of the M non-orthogonal layers, m≤M, and m is a positive integer; the network device is based on the layer sequence number and the M non-orthogonal layer And determining, by the group identifier of each of the plurality of complex symbol groups, a mapping rule corresponding to the N complex symbol groups; wherein, the s _m complex symbol groups corresponding to the _mth non-orthogonal layer respectively The mapping rule is determined by the network device according to the group identifier corresponding to the s _m complex symbol groups corresponding to the mth non-orthogonal layer and the layer sequence number of the mth non-orthogonal layer.

It should be understood that the network device determines the layer sequence numbers of the M non-orthogonal layers, where the network device determines the layer sequence number of the non-orthogonal layer corresponding to the terminal device that sends the uplink signal. The method for determining, by the network device, the layer sequence number of the non-orthogonal layer corresponding to each terminal device that sends the uplink signal is the same. Specifically, the determining, by the network device, the layer sequence numbers of the M non-orthogonal layers may include the following two methods:

The network device may determine the layer sequence numbers of the M non-orthogonal layers according to the pilots in the uplink signal. When the uplink signal includes multiple pilots, the network device may determine, according to each pilot, at least one non-positive The layer number of the layer. The network device pre-stores the layer sequence numbers of at least one non-orthogonal layer corresponding to each pilot.

Manner 2: The network device schedules at least one terminal device to send an uplink signal. After the network device receives the uplink signal, the network device knows which terminal devices send the uplink signal, and further determines at least one non-orthogonal layer corresponding to each terminal device. Layer number. The network device pre-stores layer sequence numbers of at least one non-orthogonal layer that each terminal device should.

In a possible design, before the network device demodulates the N complex symbol groups according to mapping rules corresponding to the N complex symbol groups respectively, the network device performs scrambling processing on the uplink signal. The N complex symbol groups are subjected to de-scrambling processing to obtain the N complex symbol groups, and the scrambling sequence used in the de-scrambling process is based on the first parameter, the time domain resource sequence number, At least one parameter of the cell identifier is determined.

In a possible design, the network device determines a mapping rule corresponding to the N complex symbol groups in the uplink signal, which may be, but is not limited to, the following method: the network device is configured according to the uplink signal. Determining, by the pilot, the hopping offset; the network device determining, according to the hopping offset and the group identifier of each complex symbol group in the N complex symbol groups, that the N complex symbol groups respectively correspond Mapping rules.

It is assumed that a total of Q mapping rules are predefined in the system, wherein the mapping rule corresponding to the i-th bit group is the q-th mapping rule (0 ≤ i ≤ N-1, 0 ≤ q ≤ Q-1), The q mapping rules can be determined by any of the following formulas:

Equation 1: q = (start of jump + i * jump offset) mod Q

Equation 2: q = (i * hopping offset) mod Q

Equation 3: q = (start of jump + i' * jump offset) mod Q

Where i' = i modQ', where Q' is an integer greater than one.

The network device may configure the hopping offset and the hopping starting amount to the terminal device by using an RRC message or a DCI. Furthermore, the hopping start amount can also be determined by the terminal device itself. In a possible design, the hopping start quantity may be determined according to one or more parameters in the time domain resource sequence number, the cell identifier, the pilot parameter, the non-orthogonal layer sequence number, and the terminal device identifier.

In a possible design, before the network device demodulates the N complex symbol groups according to the mapping rules corresponding to the N complex symbol groups respectively, the network device further includes:

Decoding, by the network device, the N complex symbol groups that are interleaved in the uplink signal to obtain the N complex symbol groups, where the interleaving pattern used in the deinterleaving process is according to the Determined by at least one parameter of a parameter, the time domain resource sequence number, and the cell identifier.

In a third aspect, the present application provides a data modulation apparatus that performs the method of any of the possible aspects of the first aspect or the first aspect. In particular, the apparatus comprises means for performing the method of any of the possible aspects of the first aspect or the first aspect.

In a fourth aspect, the present application provides a data demodulating apparatus that performs the method of any one of the possible aspects of the second aspect or the second aspect. In particular, the apparatus comprises means for performing the method of any of the possible aspects of the second aspect or the second aspect.

In a fifth aspect, the application provides a terminal device, where the terminal device includes a transceiver, a processor, and a memory: the memory is used to store a computer program; the processor calls the computer program stored in the memory, by using the The transceiver performs the method of any of the possible aspects of the first aspect or the first aspect.

In a sixth aspect, the application provides a network device, the network device including a transceiver, a processor, and a memory: the memory is used to store a computer program; the processor invokes the computer program stored in the memory, by The transceiver performs the method of any of the possible aspects of the first aspect or the first aspect.

For specific implementation steps, refer to the first aspect and the second aspect, which are not described herein.

In a seventh aspect, the present application also provides a computer readable storage medium storing a computer program that, when executed on a computer, causes the computer to perform the methods described in the above aspects.

In an eighth aspect, the present application also provides a computer program product comprising a program, which when executed on a computer, causes the computer to perform the method described in the above aspects.

DRAWINGS

1 is a schematic diagram of a non-orthogonal transmission scenario in an embodiment of the present application;

2 is a flowchart of an overview of a data modulation method in an embodiment of the present application;

3 is a flowchart of an overview of a data demodulation method in an embodiment of the present application;

4 is a schematic structural diagram of a data modulation apparatus according to an embodiment of the present application;

FIG. 5 is a schematic structural diagram of a data demodulating apparatus according to an embodiment of the present application;

FIG. 6 is a schematic structural diagram of a terminal device according to an embodiment of the present application;

FIG. 7 is a schematic structural diagram of a network device in an embodiment of the present application.

Detailed ways

Embodiments of the present application will be described below with reference to the accompanying drawings.

The network device involved in the embodiment of the present application is an access device that is accessed by the terminal device to the mobile communication system by using a wireless device, and may be a base station, an evolved base station (eNodeB), a base station in a 5G mobile communication system, and a next-generation mobile station. The specific technology and the specific device configuration adopted by the network device are not limited in the embodiment of the present application, such as the next generation Node B (gNB), the base station in the future mobile communication system, or the access node in the Wi-Fi system.

The terminal equipment involved in the embodiments of the present application may also be referred to as a terminal, a user equipment (UE), a mobile station (MS), a mobile terminal (MT), and the like. The terminal device can be a mobile phone, a tablet, a computer with wireless transceiver function, a virtual reality (VR) terminal device, an augmented reality (AR) terminal device, industrial control (industrial control) Wireless terminal, wireless terminal in self-driving, wireless terminal in remote medical surgery, wireless terminal in smart grid, transportation safety A wireless terminal, a wireless terminal in a smart city, a wireless terminal in a smart home, and the like.

As shown in FIG. 1, it is a schematic diagram of a non-orthogonal transmission scenario. In the existing non-orthogonal transmission system, due to the limited number of mapping rules, there may be cases where different terminal devices generate signals by using similar or identical mapping rules, and the interference between signals generated by similar or identical mapping rules is relatively better. Strong, easily lead to network device demodulation failure.

It should be understood that the embodiment of the present application is mainly applied to a scenario of non-orthogonal transmission, which is used to optimize a data modulation method adopted by a terminal device, and improve a demodulation success rate of the network device.

Referring to FIG. 2, an embodiment of the present application provides a data modulation method, where the method includes:

Step 200: The terminal device divides the data to be transmitted into N bit groups.

Wherein N ≥ 2 and N is an integer.

For example, the data to be transmitted includes m*N bits, and assuming that each bit group includes m bits, the terminal device divides the m*N bits into N bit groups.

In one possible design, the data to be transmitted is obtained by at least one of error correction coding, bit level interleaving, or bit level scrambling. The data to be transmitted may be composed of one or more coding blocks or a part of one coding block.

In one possible design, the network device configures the number of bits included in each bit group for the terminal device and the total number of bits per data to be transmitted. Wherein, the number of bits included in each bit group may be different. In another possible design, the number of bits included in the bit group may be preset, for example, as specified by the standard.

For example, the network device configures the total number of bits of the data to be transmitted of the terminal device A to be X, and the number of bits included in each of the first N1 bit groups is Y1, and each of the subsequent N-N1 bit groups includes When the number of bits is Y2, N1*Y1+(N-N1)*Y2=X, Y1≠Y2, and X, N1, Y1, and Y2 are all positive integers.

Step 210: The terminal device generates N complex symbol groups.

The i-th complex symbol group is processed by using the mapping rule corresponding to the i-th bit group to process the i-th bit group, and the mapping rule corresponding to the i-th bit group is based on the group identifier of the i-th bit group. Determining, by the first parameter, the first parameter includes at least one of a pilot parameter, a hopping identifier, a terminal device identifier, a layer sequence number of a non-orthogonal layer, and a hopping offset, where 0≤i≤N-1 and i Is an integer.

The mapping rule is a rule for mapping a bit group into a complex symbol group, wherein each bit includes two values, which are 0 and 1, respectively. Assuming that each bit group includes m bits, m bits have a total of 2 m values. Combination, each combination of values corresponds to L complex symbols.

In a possible design, the specific implementation form of the mapping rule may be a combination of a preset table and a sequence of spreading codes. The table stipulates the correspondence between 2m kinds of value combinations and 2m complex symbols, wherein one value combination corresponds to one complex number symbol. In the process of mapping data bits to be transmitted into complex symbols, according to the table, m bits included in each bit group may be mapped into one complex symbol, and the complex symbol and an extension of length L are further The frequency code sequences are multiplied to obtain L complex symbols. In this design, different mapping rules may refer to different preset tables, may also refer to different spreading code sequences, and may also mean that the preset table and the spreading code are different. The mapping rules in this design can be applied to MUSA.

In a possible design, the specific implementation form of the mapping rule may also be just a preset table. The table stipulates the correspondence between 2m kinds of value combinations and 2m complex symbol groups. Wherein, a combination of values corresponds to a complex symbol group, and each symbol group includes L complex symbols. In the process of mapping data bits to be transmitted into complex symbols, m bits included in each bit group may be directly mapped into a complex symbol group including L complex symbols according to the table. Optionally, the L complex symbols may include multiple zeros. The mapping rules in this design can be applied to SCMA.

In one possible design, the specific implementation form of the mapping rule may be two preset forms. Table 1 stipulates the correspondence between 2m kinds of value combinations and 2m complex symbols. One type of value combination corresponds to one complex number, and Table 2 stipulates the correspondence between the 2m complex symbols and 2m complex symbol groups. Wherein a complex symbol corresponds to a complex symbol group, and each complex symbol group includes L complex symbols. In the process of mapping the data bits to be transmitted into complex symbols, the m bits included in each bit group may be mapped into one complex symbol according to Table 1, and then the complex symbol is mapped to 1 according to Table 2. Multiple symbol groups. In this design, different mapping rules may refer to different forms of Table 1, or may refer to different forms of Table 2, and may also mean that both Table 1 and Table 2 are different. The mapping rules in this design can be applied to PDMA.

In a possible design, the specific implementation form of the mapping rule may be a combination of a preset table and an interlaced pattern. The table stipulates a correspondence between 2m kinds of value combinations and 2m complex symbols, wherein one value combination corresponds to one complex number symbol. In the process of mapping data bits to be transmitted into complex symbols, m bits included in each bit group may be mapped into one complex symbol according to the table, and then the complex symbols are interleaved according to the interleaving pattern. A set of complex symbols including L complex symbols is obtained. In this design, different mapping rules may refer to different tables, or may refer to different interleaving patterns, or may refer to different tables and interleaving patterns. The mapping rules in this design can be applied to IGMA.

It should be noted that the table mentioned in the foregoing embodiment is only a specific form of realizing the correspondence between a bit (group) and a complex symbol (group), and it can be understood that the correspondence between a bit (group) and a complex symbol (group) is understood. The implementation of the relationship may also have other forms, which are not limited in this application.

In the above four first parameters, the pilot parameters are configured by the network device for the terminal device, or the terminal device selects the pilot parameters in the set of pilot parameters. The pilot parameters can be used to generate a demodulation reference signal (DMRS), and can also be used to generate a random access preamble. The pilot parameter is at least one of an antenna port number corresponding to the pilot, a generation parameter of the pilot sequence, or a time-frequency resource location occupied by the pilot.

The hopping identifier is configured by the network device for the terminal device, and the different terminal devices have different hopping identifiers, and the network device has a corresponding relationship between the pilot configured for the terminal device and the hopping identifier configured for the terminal device. Specifically, the network device may notify the terminal device of the hopping identifier by using a radio resource control (RRC) message or a downlink control information (DCI).

The terminal device identifier is a radio network temporary identity (RNTI), or an RRC identifier, or a temporary mobile subscriber identify (TMSI), and the pilot device configured by the network device for the terminal device is There is a corresponding relationship between terminal device identifiers.

Each non-orthogonal layer corresponds to a layer index of a non-orthogonal layer. The terminal device may use multiple non-orthogonal layers to transmit data to be sent. When the first parameter includes the layer sequence number of the non-orthogonal layer, the mapping rule corresponding to the i-th bit group is based on the group identifier of the i-th bit group. Determined by the layer number of the non-orthogonal layer that transmits the i-th bit group.

For example, for the SCMA technology, the data to be transmitted of each terminal device can be transmitted by using multiple SCMA-layers. For example, the number of layers of the SCMA-layer is 2, and the terminal device divides the data to be transmitted into 4 groups of bits, wherein the first bit group and the second bit group are transmitted by SCMA-layer1, and the first bit group corresponds to The mapping rule is determined according to the group identifier of the first bit group and the layer sequence number of the SCMA-layer1, and the mapping rule corresponding to the second bit group is determined according to the group identifier of the second bit group and the layer sequence number of the SCMA-layer1; The bit group and the fourth bit group are transmitted by SCMA-layer 2, and the mapping rule corresponding to the third bit group is determined according to the group identifier of the third bit group and the layer sequence number of SCMA-layer 2, and the fourth bit group corresponds to The mapping rule is determined according to the group identifier of the 4th bit group and the layer sequence number of SCMA-layer2.

The mapping rule corresponding to the i-th bit group may be determined according to the group identifier of the i-th bit group and the frequency hopping offset. It is assumed that a total of Q mapping rules are predefined in the system, wherein the mapping rule corresponding to the i-th bit group is the q-th mapping rule (0 ≤ i ≤ N-1, 0 ≤ q ≤ Q-1), the qth The mapping rule can be determined by any of the following formulas:

Equation 1: q = (start of jump + i * jump offset) mod Q

Equation 2: q = (i * hopping offset) mod Q

Equation 3: q = (start of jump + i' * jump offset) mod Q

Where i' = i modQ', where Q' is an integer greater than one.

The network device can configure the hopping offset and the hopping starting amount to the terminal device through RRC or DCI.

If the qth mapping rule is determined according to the formula 1, the network device may configure different hopping starting amounts for different terminal devices, and configure the same hopping offset for different terminal devices; or, the network device may be different terminals. The device has the same hopping start amount, and different hopping offsets are configured for different terminal devices. Alternatively, the network device can configure different hopping starting times for different terminal devices, and configure different hops for different terminal devices. Variable offset.

If the qth mapping rule is determined according to Equation 2, the network device needs to configure different hopping offsets for different terminal devices.

In addition, the hopping start amount may also be determined by the terminal device itself. In one possible design, the hopping start amount may be based on the time domain resource sequence number, the cell identifier, the pilot parameter, the non-orthogonal layer sequence number, and the terminal. One or more parameters in the device identification are determined. It should be understood that the parameters used to calculate the hopping start amount may be preset, for example, as specified by the standard, or configured by the network device for the terminal device.

Also, in one possible design. The network device may further configure an indication parameter for the terminal device, where the indication parameter is used to indicate whether the terminal device adopts a data modulation method as shown in FIG. 2, and the indication parameter is a hopping enable identifier. The network device may configure the indication parameter for the terminal device through an RRC message or a DCI. In addition, the corresponding indication parameters need to be separately configured for the grant-based mode and the grant-free transmission/transmission without grant mode, or the corresponding indication parameters may be independently configured for different logical channels. .

It should be understood that for the hopping identifier in the first parameter, the parameters such as the period P in the second parameter may be configured by the network device for the terminal device through the RRC message or/and the DCI. For the pilot parameters in the first parameter, the terminal device identifier, the cell identifier in the second parameter, the time domain resource sequence number and the like can reuse the existing configuration scheme in the prior art.

Since the mapping rule corresponding to each bit group is determined according to the group identifier and the first parameter of the bit group, and the group identifiers of the different bit groups are different, the mapping rules corresponding to the N bit groups respectively include at least two Different mapping rules.

In a possible design, the mapping rule corresponding to the i-th bit group is determined according to the group identifier, the first parameter, and the second parameter of the i-th bit group, and the second parameter includes a cell identifier, a time domain resource sequence number, and And at least one of the periods P.

Among the above three second parameters, the time domain resource sequence number may refer to a subframe number, a slot number, and the like.

For the period P, the formula 1 is satisfied: i=j+nP, P≥2, 0≤j<P, n≥0, and j, n, and P are integers.

Or, for the period P, the formula 2 is satisfied: j=i mod P, P≥2, 0≤j<P, j, P are integers.

For i and j satisfying the above formula, the mapping rule corresponding to the i-th bit group is the same as the mapping rule corresponding to the j-th bit group.

For example, N=6, P=3, assuming that the mapping rule corresponding to the 0th bit group is A, the mapping rule corresponding to the 1st bit group is B, and the mapping rule corresponding to the 2nd bit group is C, then the third The mapping rule corresponding to the bit group is A, the mapping rule corresponding to the fourth bit group is B, and the mapping rule corresponding to the fifth bit group is C. That is, starting from the 0th bit group, every 3 bit groups are a group, and 3 mapping rules are cyclically used in order.

In addition, in a possible design, when the terminal device needs to perform repeated transmission of data to be transmitted, the mapping rule corresponding to the N bit groups at each transmission is the same as the mapping rule corresponding to the N bit groups at the time of the first transmission.

Specifically, as an optional embodiment, when the data to be sent is transmitted in the kth time, determining a time domain resource sequence number used by the mapping rule corresponding to the N bit groups and determining N when the data to be sent is first transmitted is determined. The mapping rule corresponding to the bit group uses the same time domain resource number, where k=1, . . . K, K is the maximum number of repeated transmissions.

As an optional embodiment, when determining that the parameter used by the mapping rule corresponding to the N bit groups does not include the time domain resource sequence number, the mapping rule corresponding to the N bit groups in the kth transmission and the N bits in the first transmission The mapping rules corresponding to the group are the same.

Step 220: The terminal device sends N complex symbol groups.

Before the terminal device sends the N complex symbol groups, the terminal device may further perform scrambling processing or interleaving processing on the N complex symbol groups.

In a possible design, the terminal device performs scrambling processing on the N complex symbol groups, and the terminal device transmits the scrambled processed signals of the N complex symbol groups.

The scrambling sequence used in the scrambling process is determined according to at least one of a first parameter, a time domain resource sequence number, and a cell identifier.

It should be understood that the terminal device scrambling the N complex symbol groups means that the terminal device performs a scrambling process on the sequence consisting of N complex symbol groups by using a scrambling sequence.

Specifically, the scrambling sequence may be generated by a pseudo-random sequence generator, and the generating the scrambling sequence needs to input an initial value to the pseudo-random sequence generator, where the initial value is at least one of the first parameter, the cell identifier, and the time domain resource sequence number. A parameter is determined.

For example, c_init is an initial value, c_init=terminal device identifier*2 ^A + time domain resource sequence number*2 ^B + cell identifier, where A and B are preset positive integers. Entering c_init into the binary pseudo-random sequence generator can generate a binary pseudo-random sequence c(s), where s=0,...,2S-1,S is the sequence length and c(s) is dependent on c_init generation.

For example, c(s)=1/sqrt(2)*(1-2*c(2s))+j*1/sqrt(2)*(1-2*c(2s+1)), s=0 ,...,S-1, where S is the sequence length, j=sqrt(-1), and sqrt() represents the square root.

It should be understood that the bit stream is scrambled in the prior art, and the scrambling process in the embodiment of the present application is for a complex symbol stream.

In a possible design, the terminal device performs interleaving processing on the N complex symbol groups, and the terminal device transmits the signals of the N complex symbol groups after the interleaving process.

The interlace pattern used in the interleaving process is determined according to at least one of a first parameter, a time domain resource sequence number, and a cell identifier.

It should be understood that the interleaving process is to rearrange N complex symbol groups, and the interleaving pattern refers to the rule of rearrangement.

For example, when the interleaving process is matrix interleaving, the interleaving pattern is determined by the number of rows of matrix interleaving, wherein the number of rows of the matrix interlacing = g (cell identity, time domain resource sequence number, terminal device identifier), where g is a preset function .

Similarly, the prior art performs interleaving processing on the bit stream, and the interleaving processing in the embodiment of the present application is directed to a complex symbol stream.

In the prior art, in a non-orthogonal transmission system, in order to enable a network device to distinguish signals corresponding to multiple terminal devices on the same resource, signals transmitted by different terminal devices need to have different signal characteristics, such as different terminal devices. The transmitted signals are generated by different mapping rules, or the signals sent by different terminal devices are scrambled by different scrambling sequences, or the signals transmitted by different terminal devices are interleaved by different interleaving patterns. Therefore, different terminal devices send The signals have different signatures. Different signatures can refer to different mapping methods, and/or different interleaving methods, and/or different scrambling methods.

It should be understood that the N complex symbol groups subjected to the scrambling process are not limited to the N complex symbol groups obtained by using the embodiment shown in FIG. 1 , and may also be applied to the obtained complex symbol groups by other mapping schemes. This is not limited. Similarly, the N complex symbol groups subjected to the interleaving process are not limited to the N complex symbol groups obtained by using the embodiment shown in FIG. 1 , and may also be applied to the obtained complex symbol groups by other mapping schemes. limited.

In summary, using the method provided in the embodiment shown in FIG. 1, the terminal device divides the data to be transmitted into N bit groups, and then processes the bit group by using a mapping rule corresponding to each bit group to generate N complex symbols. a group, wherein a mapping rule corresponding to each bit group is determined according to a group identifier of the bit group and a first parameter. Because the first parameters of different terminal devices are different, a set of mapping rules adopted by different terminal devices will not be identical, thereby realizing interference between randomized terminal devices and solving similar or identical mappings of multiple terminal devices. The rule generation signal causes the network device to fail to decode, and improves the success rate of network device demodulation.

The embodiment shown in FIG. 1 will be described in detail below with reference to specific embodiments.

Example 1:

The network device configures pilot parameters for the terminal device. The data to be transmitted includes m*N bits, and assuming that each bit group includes m bits, the terminal device divides the m*N bits into N bit groups.

Optionally, the m*N bits may be obtained after at least one of error correction coding, bit level interleaving, or bit level scrambling.

It is assumed that a total of Q mapping rules are predefined in the system, wherein the nth bit group adopts the qth mapping rule (0 ≤ n ≤ N-1, 0 ≤ q ≤ Q-1), and each group includes m bits. Is mapped to L complex symbols.

If the network device and the terminal device agree to determine the parameters of the mapping rule, including: a cell identifier, a slot number, a pilot parameter, a group identifier of the bit group, and a total number of mapping rules, the qth mapping rule adopted by the nth bit group, It can be determined by the following formula:

q=mod(f(cell identity, slot number, pilot parameter, n), Q)(1)

Where f(x) is an arbitrary function.

Specifically, when the pilot parameter is the antenna port number corresponding to the pilot, the qth mapping rule adopted by the nth bit group may be any one of the following formulas:

or

Where c is a pseudo-random sequence (eg, Gold sequence, m-sequence, etc.), the initial value of the pseudo-random sequence is Cinit, c depends on Cinit, P1, P2, and P3 are preset integers, and the range of values of P1, P2, and P3 Is any integer.

If the network device and the terminal device agree to determine the parameters of the mapping rule, including the cell identifier, the slot number, the pilot parameter, the group identifier of the bit group, the total number of mapping rules, and the period P, the qth type adopted by the nth bit group Mapping rules can be determined by the following formula:

q=mod(f(cell identity, slot number, pilot parameter, mod(n,P), Q) (5)

Where f(x) is an arbitrary function.

or

Where c is a pseudo-random sequence (eg, Gold sequence, m-sequence, etc.), the initial value of the pseudo-random sequence is Cinit, c is determined by Cinit, n'=n mod P, P1, P2, P3 are arbitrary integers.

Finally, the terminal device generates N complex symbol groups, each complex symbol group including L complex symbols, that is, the terminal device maps m*N bits into m*L complex symbols.

Optionally, if the terminal device needs to perform K times of repeated transmission, the mapping rule corresponding to the N bit groups in each transmission is the same as the mapping rule corresponding to the N bit groups in the first transmission.

If the network device and the terminal device agree to determine the parameters of the mapping rule, including the cell identifier, the slot number, the pilot parameter, the group identifier of the bit group, and the total number of mapping rules, the terminal device transmits k (k=2...K) times. The qth mapping rule adopted by the nth bit group is the same as the qth mapping rule adopted by the nth bit group when the terminal device repeats the first transmission, and the qth mapping rule adopted by the nth bit group It can be determined by the following formula:

q=mod(f(cell identity, slot number of the first transmission, pilot parameter, n), Q) (9)

or

Where c is a pseudo-random sequence (eg, Gold sequence, m-sequence, etc.), the initial value of the pseudo-random sequence is Cinit, c is determined by Cinit, and P1, P2, and P3 are arbitrary integers.

If the network device and the terminal device agree to determine the parameters of the mapping rule, including the cell identifier, the slot number, the pilot parameter, the group identifier of the bit group, the total number of mapping rules, and the period P, the nth time when the terminal device repeats the transmission for the Kth time The qth mapping rule adopted by the bit group is the same as the qth mapping rule adopted by the nth bit group when the terminal device repeats the first transmission, and the qth mapping rule adopted by the nth bit group may be as follows The formula determines:

q=mod(f(cell identity, slot number of the first transmission, pilot parameter, mod(n, P)), Q) (13)

or

If the network device and the terminal device agree to determine the parameters of the mapping rule, including: the cell identifier, the pilot parameter, the group identifier of the bit group, and the total number of mapping rules, the qth type used by the nth bit group when the terminal device repeats the Kth transmission The mapping rule is the same as the qth mapping rule adopted by the nth bit group when the terminal device repeats the first transmission, and the qth mapping rule adopted by the nth bit group can be determined by the following formula:

q=mod(f(cell identity, pilot parameter, n), Q) (17)

Where c is a pseudo-random sequence (eg, Gold sequence, m-sequence, etc.), the initial value of the pseudo-random sequence is Cinit, c is determined by Cinit, and P1, P2 are arbitrary integers.

If the network device and the terminal device agree to determine the parameters of the mapping rule, including: the cell identifier, the pilot parameter, the group identifier of the bit group, and the total number of mapping rules, and the period P, the qth mapping rule adopted by the nth bit group may Determine by the following formula:

q=mod(f(cell identity, pilot parameter, mod(n,P)), Q) (19)

Where c is a pseudo-random sequence (eg, Gold sequence, m-sequence, etc.), the initial value of the pseudo-random sequence is Cinit, c is determined by Cinit, n'=n mod P, P1, P2 are arbitrary integers.

In one implementation, the pilot parameters, the hopping identifier, and the terminal device identifier in the above formula may be replaced with the layer sequence number of the non-orthogonal layer. In another embodiment, it is also possible to add a layer number of the non-orthogonal layer to the calculation formula of the initial value Cinit of the pseudo-random sequence, for example, after each initial value Cinit formula, add "2P4* non-positive Layer number of the layer of intersection, where P4 is a preset integer.

It should be noted that the foregoing formula for determining the mapping rule is only an example, and other implementation manners are also possible, which are not limited in this application.

Example 2:

The network device configures a pilot parameter and a hopping identifier for the terminal device, where the hopping identifier has a corresponding relationship with the pilot parameter. Based on the method for determining the mapping rule corresponding to each bit group shown in Embodiment 1, if the first parameter used by the network device and the terminal device for determining the mapping rule is a hopping identifier, the guiding in Embodiment 1 may be directly adopted. The frequency parameter or the antenna port number is replaced with a hopping identifier, and the mapping rule corresponding to each bit group determined by the hopping identifier is obtained, and the repeated description is not repeated.

Example 3:

The network device configures a pilot parameter for the terminal device, where the terminal device identifier has a corresponding relationship with the pilot parameter.

The method of determining the mapping rule corresponding to each bit group according to the embodiment 1 is: if the first parameter used by the network device and the terminal device to determine the mapping rule is the terminal device identifier, the guiding in the first embodiment may be directly adopted. The frequency parameter or the antenna port number is replaced with the terminal device identifier, and the mapping rule corresponding to each bit group determined by the terminal device identifier is obtained, and the repeated description is not repeated.

Referring to FIG. 3, an embodiment of the present application provides a data demodulation method, where the method includes:

Step 300: The network device receives the uplink signal.

It should be understood that the uplink signal may include an uplink signal from one terminal device, and may also include an uplink signal from multiple terminal devices.

Step 310: The network device determines a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, where N≥2 and N is an integer.

Step 320: The network device demodulates the corresponding complex symbol group according to mapping rules corresponding to the N complex symbol groups.

The mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier of the i-th complex symbol group and the first parameter, where the first parameter includes a pilot parameter, a hopping identifier, a terminal device identifier, and a non-positive At least one of a layer sequence number and a hopping offset of the intersecting layer; the mapping rule corresponding to each of the N complex symbol groups includes at least two mapping rules different from each other, 0≤i≤N-1 and i is an integer .

It should be understood that the network device knows the number of complex symbols included in each complex symbol group and is capable of determining the number of complex symbol groups included in the uplink signal.

For example, the uplink signal includes N×L complex symbols, and assuming each complex symbol group includes L complex symbols, N complex symbol groups are determined.

If the network device detects a pilot in the uplink signal, the network device according to the pilot parameter corresponding to the pilot, or the hop identifier corresponding to the pilot, or the terminal device identifier corresponding to the pilot, or the pilot Corresponding hopping offsets are used to determine mapping rules corresponding to the N complex symbol groups, and the network device demodulates the corresponding complex symbol groups according to mapping rules corresponding to the N complex symbol groups, and performs subsequent processing on the demodulation results. N bit groups. Or, if the network device detects a pilot in the uplink signal, the network device determines, according to the layer sequence number of the at least one non-orthogonal layer corresponding to the pilot, a corresponding one of the N complex symbol groups corresponding to each non-orthogonal layer. At least one complex symbol group, and further determining a mapping rule corresponding to each of the N complex symbol groups, and the network device demodulates the corresponding complex symbol group according to the mapping rules corresponding to the N complex symbol groups respectively, and performs subsequent processing on the demodulation result to obtain N Bit groups.

If the network device detects multiple pilots in the uplink signal, the network device according to the pilot parameters corresponding to each pilot, or the hopping identifier corresponding to each pilot, or the terminal device identifier corresponding to each pilot, Or a layer sequence number of at least one non-orthogonal layer corresponding to each pilot, or a hopping offset corresponding to each pilot, determines a mapping rule corresponding to each pilot, and each group of mapping rules includes N complex symbols The corresponding mapping rule is set by the network device, and the network device demodulates the corresponding complex symbol group according to a set of mapping rules corresponding to each pilot, and performs subsequent processing on the demodulation result to obtain N bit groups corresponding to each pilot.

Here, the subsequent processing of the demodulation result includes bit level de-interference, and/or bit-level de-interleaving, and the like.

For example, it is assumed that the terminal device A and the terminal device B respectively transmit N complex symbol groups to the network device on the same resource, and the network device detects two pilots in the received uplink signal, and the network device responds according to each pilot. The pilot parameters determine a set of mapping rules corresponding to each pilot. Each group of mapping rules includes mapping rules corresponding to N complex symbol groups. Therefore, two mapping rules are obtained. The network device uses the two sets of mapping rules to demodulate the N complex symbol groups in the uplink signal, and performs subsequent processing on the demodulation result to obtain N bit groups corresponding to the two pilots respectively.

It should be understood that the terminal device A generates N mapping rules adopted by the N complex symbol groups, and the mapping rules may be the same as the N mapping rules used by the terminal device B to generate the N complex symbol groups. Therefore, when the network device uses the two sets of mapping rules to demodulate the N complex symbol groups in the uplink signal, the complex symbol group generated by using the same mapping rule may demodulate, but the terminal device A generates N complex symbols. The N mapping rules adopted by the group are mostly different from the N mapping rules used by the terminal device B to generate the N complex symbol groups, so the network device can correctly demodulate most of the complex symbol groups, thereby improving the demodulation success rate.

The network device determines the parameters used by the mapping rule for the terminal device configuration, and specifically includes the following possible forms:

Manner 1: The network device determines, for the terminal device, that the parameter used by the mapping rule corresponding to the i-th complex symbol group includes a pilot parameter.

Therefore, the network device can determine mapping rules corresponding to the N complex symbol groups according to the pilot parameters corresponding to one pilot in the uplink signal and the group identifier corresponding to the N complex symbol groups.

The mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier and the pilot parameter of the i-th complex symbol group.

Manner 2: The network device determines, for the terminal device configuration, that the parameter used by the mapping rule corresponding to the i-th complex symbol group includes a hopping identifier.

Therefore, the network device determines, according to one pilot in the uplink signal, the hopping identifier corresponding to the pilot, and the network device can determine, according to the group identifier corresponding to the hopping identifier and the N complex symbol groups, that the N complex symbol groups respectively correspond to Mapping rules.

The mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier and the hopping identifier of the i-th complex symbol group.

Manner 3: The network device determines, for the terminal device, that the parameter used by the mapping rule corresponding to the i-th complex symbol group includes a terminal device identifier.

Therefore, the network device determines, according to one pilot in the uplink signal, the terminal device identifier corresponding to the pilot, and the network device can determine that the N complex symbol groups respectively correspond to the group identifier corresponding to the terminal device identifier and the N complex symbol groups. Mapping rules.

The mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier of the i-th complex symbol group and the terminal device identifier.

Manner 4: The network device determines, for the terminal device configuration, that the parameter used by the mapping rule corresponding to the i-th complex symbol group includes a layer sequence number of the non-orthogonal layer.

Therefore, the network device determines the layer sequence numbers of the M non-orthogonal layers, and M is a positive integer.

Mode A: The network device may determine a layer sequence number of the M non-orthogonal layers according to the pilot in the uplink signal. When the uplink signal includes multiple pilots, the network device may determine, according to each pilot, at least one non-positive The layer number of the layer. The network device pre-stores the layer sequence numbers of at least one non-orthogonal layer corresponding to each pilot.

Mode B: The network device schedules at least one terminal device to send an uplink signal, and after the network device receives the uplink signal, the network device knows which terminal devices send the uplink signal, and further determines at least one non-orthogonal layer corresponding to each terminal device. Layer number. The network device pre-stores layer sequence numbers of at least one non-orthogonal layer that each terminal device should. The network device first determines at least one complex symbol group corresponding to each of the M non-orthogonal layers of the N complex symbol groups. Wherein, the mth non-orthogonal layer corresponds to s _m complex symbol groups,

The mth non-orthogonal layer is any one of M non-orthogonal layers, m≤M, and m is a positive integer.

Then, the network device determines a mapping rule corresponding to the N complex symbol group according to the layer sequence number of the M non-orthogonal layers and the group identifier of each of the complex symbol groups of the N complex symbol groups; wherein, the mth non-positive The mapping rule corresponding to the s _m complex symbol groups corresponding to the intersecting layer is a group identifier and an mth non-orthogonal layer respectively corresponding to the s _m complex symbol groups corresponding to the mth non-orthogonal layer by the network device The layer number is determined, and the mth non-orthogonal layer is any one of M non-orthogonal layers, m≤M, and m is a positive integer.

The mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier of the i-th complex symbol group and the layer sequence of the non-orthogonal layer corresponding to the i-th complex symbol group.

Manner 5: The network device determines, for the terminal device configuration, that the parameter used by the mapping rule corresponding to the i-th complex symbol group includes a hopping offset.

Therefore, the network device determines, according to one pilot in the uplink signal, a hopping offset corresponding to the pilot, and the network device can determine N complex numbers according to the hopping offset and the group identifier corresponding to the N complex symbol groups respectively. The mapping rules corresponding to the symbol groups respectively.

The mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier and the hopping offset of the ith complex symbol group.

Similarly, the parameter that the network device uses to determine the mapping rule for the terminal device configuration may further include a second parameter, where the second parameter includes at least one of a cell identifier, a time domain resource sequence number, and a period P.

In addition, in a possible design, before the network device demodulates the N complex symbol groups according to the mapping rules corresponding to the N complex symbol groups, the network device needs to perform the scrambled N complex symbol groups in the uplink signal. The scrambling process is performed to obtain N complex symbol groups, and the scrambling sequence used in the de-scrambling process is determined according to at least one parameter of the first parameter, the time domain resource sequence number, and the cell identifier.

It should be understood that the scrambling sequence used by the terminal device to perform scrambling processing on the N complex symbol groups before the terminal device transmits the N complex symbol groups, and the network device pair N before the network device demodulates the N complex symbols. The scrambling sequence used for the de-scrambling process of the complex symbol group is the same.

In a possible design, before the network device demodulates the N complex symbol groups according to the mapping rules corresponding to the N complex symbol groups, the network device needs to deinterleave the N complex symbol groups processed by the interleaving in the uplink signal. Obtaining N complex symbol groups, and the interleaving series used in the deinterleaving process is determined according to at least one parameter of the first parameter, the time domain resource sequence number, and the cell identifier.

It should be understood that, before the terminal device sends the N complex symbol groups, the terminal device performs an interleaving pattern on the N complex symbol groups for interleaving, and before the network device demodulates the N complex symbols, the network device pairs N complex numbers. The interleaving pattern used by the symbol group for deinterleaving is the same.

It should be understood that both A mod B and mod (A, B) represent the modulo operation of A to B, namely A-floor(A/B)*B, where floor() represents rounding down.

Based on the above embodiment, the embodiment of the present application provides a data modulation device. As shown in FIG. 4, the device 400 includes:

The processing unit 401 is configured to divide the data to be sent into N bit groups, N≥2 and N is an integer;

Generating N complex symbol groups, wherein the i-th complex symbol group is processed by processing the i-th bit group by using a mapping rule corresponding to the i-th bit group, and mapping rules corresponding to the i-th bit group And determining, according to the group identifier and the first parameter of the i-th bit group, the first parameter includes a pilot parameter, a hopping identifier, a terminal device identifier, a layer sequence number of a non-orthogonal layer, and a hopping offset At least one of the mapping rules corresponding to the N bit groups respectively includes at least two mapping rules different from each other, 0≤i≤N-1 and i is an integer;

The sending unit 402 is configured to send the N complex symbol groups.

In a possible design, when the data to be transmitted is repeatedly transmitted, the mapping rule corresponding to the N bit groups is the same as the mapping rule corresponding to the N bit groups at the time of the first transmission. .

In a possible design, the processing unit 401 is further configured to:

Performing a scrambling process on the N complex symbol groups before transmitting the N complex symbol groups, wherein the scrambling sequence used in the scrambling process is based on the first parameter, the time domain resource Determining, by a sequence number, at least one parameter in the cell identifier;

The sending unit 402 is specifically configured to:

Transmitting the signal of the N complex symbol groups after scrambling.

In a possible design, the processing unit 401 is further configured to:

Interleaving the N complex symbol groups before transmitting the N complex symbol groups, where the interleaving pattern used in the interleaving process is based on the first parameter, the time domain resource sequence, and the Determining at least one parameter in the cell identifier;

The sending unit 402 is specifically configured to:

Transmitting the signal of the N complex symbol groups after interleaving.

For a specific implementation manner of the function module included in the data modulating device of FIG. 4 and the corresponding beneficial effects, reference may be made to the specific description of the foregoing embodiment shown in FIG. 2, and details are not described herein.

As another optional variant, the embodiment of the present application provides a data modulation device, which may exemplarily be a chip, which includes a processor and an interface. The processor completes the function of the processing unit 401, and the interface completes the function of the sending unit 402 for outputting N complex symbol groups. The apparatus can also include a memory for storing a program executable on the processor, the processor performing the method described in the above embodiments.

Based on the above embodiment, the embodiment of the present application provides a data demodulating apparatus. As shown in FIG. 5, the apparatus 500 includes:

The receiving unit 501 is configured to receive an uplink signal.

The processing unit 502 is configured to determine a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, where N≥2 and N is an integer;

Demodulating a corresponding complex symbol group according to a mapping rule corresponding to each of the N complex symbol groups;

The mapping rule corresponding to the ith complex symbol group is determined according to the group identifier of the ith complex symbol group and the first parameter, where the first parameter includes a pilot parameter, a hopping identifier, and a terminal device. At least one of an identifier, a layer sequence number of the non-orthogonal layer, and a hopping offset; the mapping rule corresponding to the N complex symbol groups respectively includes at least two mapping rules different from each other, 0≤i≤N -1 and i is an integer.

In a possible design, the processing unit 502 is further configured to:

Determining, when the N complex symbol groups are not the first transmission, determining a mapping rule corresponding to the N complex symbol groups and a mapping rule corresponding to the N complex symbol groups when the N complex symbol groups are first transmitted respectively the same.

In a possible design, the processing unit 502 is specifically configured to:

Determining, according to the pilot in the uplink signal, a pilot parameter corresponding to the pilot;

Determining, according to the pilot parameter and a group identifier of each complex symbol group in the N complex symbol groups, mapping rules respectively corresponding to the N complex symbol groups.

In a possible design, the processing unit 502 is specifically configured to:

Determining the hopping identifier according to a pilot in the uplink signal;

Determining, according to the hopping identifier and the group identifier of each of the plurality of complex symbol groups of the N complex symbol groups, a mapping rule corresponding to the N complex symbol groups.

In a possible design, the processing unit 502 is specifically configured to:

Determining, according to the pilot in the uplink signal, the terminal device identifier;

Determining, according to the terminal device identifier and the group identifier of each of the plurality of complex symbol groups in the N complex symbol groups, a mapping rule corresponding to the N complex symbol groups.

In a possible design, the processing unit 502 is specifically configured to:

Determining the layer numbers of the M non-orthogonal layers, where M is a positive integer;

Determining at least one complex symbol group corresponding to each of the M non-orthogonal layers of the N complex symbols, wherein the mth non-orthogonal layer corresponds to sm complex symbol groups,

The mth non-orthogonal layer is any one of the M non-orthogonal layers, m≤M, and m is a positive integer;

Determining, according to a layer number of the M non-orthogonal layers and a group identifier of each of the plurality of complex symbol groups, a mapping rule corresponding to the N complex symbol groups; wherein, the mth The mapping rule corresponding to each of the sm complex symbol groups corresponding to the non-orthogonal layer is a group identifier corresponding to the sm complex symbol groups corresponding to the mth non-orthogonal layer, and the mth non-corresponding rule respectively The layer number of the orthogonal layer is determined.

In a possible design, the processing unit 502 is specifically configured to:

Determining the hopping offset according to a pilot in the uplink signal;

Determining, according to the hopping offset and the group identifier of each complex symbol group in the N complex symbol groups, mapping rules respectively corresponding to the N complex symbol groups.

In a possible design, the processing unit 502 is further configured to:

Before demodulating the N complex symbol groups according to mapping rules corresponding to the N complex symbol groups respectively, performing descrambling processing on the N complex symbol groups scrambled in the uplink signal, And the scrambling sequence used in the de-scrambling process is determined according to at least one of the first parameter, the time domain resource sequence number, and the cell identifier.

In a possible design, the processing unit 502 is further configured to:

Before demodulating the N complex symbol groups according to mapping rules respectively corresponding to the N complex symbol groups, performing deinterleaving processing on the N complex symbol groups subjected to interleaving in the uplink signal, to obtain the The N complex symbol groups are determined according to at least one of the first parameter, the time domain resource sequence number, and the cell identifier.

It is to be understood that the specific implementation of the functional blocks included in the data modulating device of FIG. 5 and the corresponding beneficial effects may be referred to the specific description of the foregoing embodiment shown in FIG. 3, and details are not described herein.

It should be understood that the division of each unit above is only a division of logical functions, and the actual implementation may be integrated into one physical entity in whole or in part, or may be physically separated. Moreover, these units may all be implemented in the form of software by means of processing component calls; or may be implemented entirely in hardware; some units may be implemented in software in the form of processing component calls, and some units may be implemented in hardware. In the implementation process, each step of the above method or each of the above units may be completed by an integrated logic circuit of hardware in the processor element or an instruction in a form of software.

For example, the above units may be one or more integrated circuits configured to implement the above methods, such as one or more Application Specific Integrated Circuits (ASICs), or one or more microprocessors (digital) Signal processor, DSP), or one or more Field Programmable Gate Arrays (FPGAs). As another example, when one of the above units is implemented in the form of a processing component scheduler, the processing element can be a general purpose processor, such as a central processing unit (CPU) or other processor that can invoke the program. As another example, these units can be integrated and implemented in the form of a system-on-a-chip (SOC).

As another optional variant, the embodiment of the present application provides a data demodulating apparatus. Illustratively, it may be a chip. The apparatus includes a processor and an interface, and the interface may be an input/output interface. The processor completes the function of the processing unit 502, and the interface completes the function of the receiving unit 501 for inputting an uplink signal. The apparatus can also include a memory for storing a program executable on the processor, the processor performing the method described in the above embodiments.

Based on the above embodiment, the embodiment of the present application further provides a terminal device, which may be a terminal device in the embodiment shown in FIG. 2, as shown in FIG. 6, the terminal device 600 includes: a transceiver 601, and processing The unit 602 and the memory 603. The memory 603 is used to store a computer program; the processor 602 calls a computer program stored in the memory 603, and the method shown in FIG. 2 is executed by the transceiver 601.

It can be understood that the data modulation apparatus in the above embodiment shown in FIG. 4 can be implemented by the terminal device 600 shown in FIG. 6. Specifically, the processing unit 401 can be implemented by the processor 602, and the sending unit 402 can be implemented by the transceiver 601. The structure of the terminal device 600 does not constitute a limitation on the embodiments of the present application.

Based on the above embodiment, the embodiment of the present application further provides a network device, which may be a network device in the embodiment shown in FIG. 3, as shown in FIG. 7, the network device 700 includes: a transceiver 701, and processing The device 702 and the memory 703. The memory 703 is used to store a computer program; the processor 702 calls a computer program stored in the memory 703, and the method shown in FIG. 3 is executed by the transceiver 701.

It can be understood that the data demodulating device in the above embodiment shown in FIG. 5 can be implemented by the network device 700 shown in FIG. Specifically, the receiving unit 501 can be implemented by the transceiver 701, and the processing unit 502 can be implemented by the processor 702. The structure of the network device 700 does not constitute a limitation on the embodiments of the present application.

In Figures 6 and 7, the processor can be a CPU, a network processor (NP), a hardware chip, or any combination thereof. The memory may include a volatile memory such as a random access memory (RAM); the memory may also include a non-volatile memory such as a read-only memory. , ROM), flash memory, hard disk drive (HDD) or solid-state drive (SSD); the memory may also include a combination of the above types of memory.

In summary, the terminal device divides the data to be transmitted into N bit groups, and then processes the bit group by using a mapping rule corresponding to each bit group to generate N complex symbol groups, where each bit group corresponds to The mapping rule is determined according to the group identifier of the bit group and the first parameter. Because the first parameters of different terminal devices are different, the mapping rules used by different terminal devices are not completely the same, thereby realizing the interference between the randomized terminal devices and improving the success rate of demodulation of the network devices. The problem that the terminal devices generate signals by using similar or identical mapping rules causes the network device to fail to decode.

Those skilled in the art will appreciate that embodiments of the present application can be provided as a method, system, or computer program product. Therefore, the embodiments of the present application may take the form of an entirely hardware embodiment, an entirely software embodiment, or an embodiment combining software and hardware. Moreover, embodiments of the present application can take the form of a computer program product embodied on one or more computer-usable storage media (including but not limited to disk storage, CD-ROM, optical storage, etc.) including computer usable program code.

Embodiments of the present application are described with reference to flowchart illustrations and/or block diagrams of methods, devices (systems), and computer program products according to embodiments of the present application. It will be understood that each flow and/or block of the flowchart illustrations and/or FIG. These computer program instructions can be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing device to produce a machine for the execution of instructions for execution by a processor of a computer or other programmable data processing device. Means for implementing the functions specified in one or more of the flow or in a block or blocks of the flow chart.

The computer program instructions can also be stored in a computer readable memory that can direct a computer or other programmable data processing device to operate in a particular manner, such that the instructions stored in the computer readable memory produce an article of manufacture comprising the instruction device. The apparatus implements the functions specified in one or more blocks of a flow or a flow and/or block diagram of the flowchart.

These computer program instructions can also be loaded onto a computer or other programmable data processing device such that a series of operational steps are performed on a computer or other programmable device to produce computer-implemented processing for execution on a computer or other programmable device. The instructions provide steps for implementing the functions specified in one or more of the flow or in a block or blocks of a flow diagram.

It is apparent that those skilled in the art can make various modifications and variations to the embodiments of the present application without departing from the spirit and scope of the application. Thus, it is intended that the present invention cover the modifications and variations of the embodiments of the present invention.

Claims

A data modulation method, the method comprising:

The terminal device divides the data to be transmitted into N bit groups, N≥2 and N is an integer;

The terminal device generates N complex symbol groups, where the i-th complex symbol group is processed by processing the i-th bit group by using a mapping rule corresponding to the i-th bit group, the i-th bit group Corresponding mapping rules are determined according to the group identifier of the i-th bit group and the first parameter, where the first parameter includes a pilot parameter, a hopping identifier, a terminal device identifier, a layer sequence number of the non-orthogonal layer, and a hop. At least one of the variable offsets; the mapping rule corresponding to the N bit groups respectively includes at least two mapping rules different from each other, 0≤i≤N-1 and i is an integer;

The terminal device sends the N complex symbol groups.
The method according to claim 1, wherein the mapping rule corresponding to the i-th bit group is determined according to the group identifier of the i-th bit group, the first parameter and the second parameter, The second parameter includes at least one of a cell identifier, a time domain resource sequence number, and a period P.
The method according to claim 1 or 2, wherein when the terminal device repeatedly transmits the data to be transmitted, the mapping rule corresponding to the N bit groups and the first transmission time are transmitted each time The mapping rules corresponding to the N bit groups are the same.
The method according to any one of claims 1-3, wherein the terminal device identifier is a radio network temporary identifier RNTI, or a radio resource control RRC identifier, or a temporary mobile subscriber identification number TMSI.
The method according to any one of claims 2-4, wherein before the sending, by the terminal device, the N complex symbol groups, the method further includes:

The terminal device performs scrambling processing on the N complex symbol groups, where the scrambling sequence used in the scrambling process is based on the first parameter, the time domain resource sequence number, and the cell identifier At least one parameter determined;

Transmitting, by the terminal device, the N complex symbol groups, including:

The terminal device sends the scrambled signal of the N complex symbol groups.
The method according to any one of claims 2-4, wherein before the sending, by the terminal device, the N complex symbol groups, the method further includes:

The terminal device performs an interleaving process on the N complex symbol groups, where the interleaving pattern used in the interleaving process is based on at least one of the first parameter, the time domain resource sequence number, and the cell identifier. Parameter determined;

Transmitting, by the terminal device, the N complex symbol groups, including:

The terminal device sends the signal after the N complex symbol groups are interleaved.
A data demodulation method, the method comprising:

The network device receives the uplink signal;

Determining, by the network device, a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, where N≥2 and N is an integer;

Decoding, by the network device, a corresponding complex symbol group according to a mapping rule corresponding to each of the N complex symbol groups;

The mapping rule corresponding to the ith complex symbol group is determined according to the group identifier of the ith complex symbol group and the first parameter, where the first parameter includes a pilot parameter, a hopping identifier, and a terminal device. At least one of an identifier, a layer sequence number of the non-orthogonal layer, and a hopping offset; the mapping rule corresponding to the N complex symbol groups respectively includes at least two mapping rules different from each other, 0≤i≤N -1 and i is an integer.
The method according to claim 7, wherein the mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier of the i-th complex symbol group, the first parameter and the second parameter. The second parameter includes at least one of a cell identifier, a time domain resource sequence number, and a period P.
The method of claim 7 or 8, further comprising:

When the network device determines that the N complex symbol groups are not first transmitted, the network device determines a mapping rule corresponding to the N complex symbol groups and the N plural numbers when the N complex symbol groups are first transmitted. The mapping rules corresponding to the symbol groups are respectively the same.
The method according to any one of claims 7-9, wherein the terminal device identifier is a radio network temporary identifier RNTI, or a radio resource control RRC identifier, or a temporary mobile subscriber identification number TMSI.
The method according to any one of claims 7 to 10, wherein the network device determines a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, including:

Determining, by the network device, a pilot parameter corresponding to the pilot according to a pilot in the uplink signal;

Determining, by the network device, a mapping rule corresponding to each of the N complex symbol groups according to the pilot parameter and a group identifier of each of the N complex symbol groups.
The method according to any one of claims 7 to 10, wherein the network device determines a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, including:

Determining, by the network device, the hopping identifier according to a pilot in the uplink signal;

Determining, by the network device, a mapping rule corresponding to each of the N complex symbol groups according to the hopping identifier and a group identifier of each of the N complex symbol groups.
The method according to any one of claims 7 to 10, wherein the network device determines a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, including:

Determining, by the network device, the terminal device identifier according to the pilot in the uplink signal;

Determining, by the network device, a mapping rule corresponding to each of the N complex symbol groups according to the terminal device identifier and a group identifier of each of the N complex symbol groups.
The method according to any one of claims 7 to 10, wherein the network device determines a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, including:

The network device determines a layer sequence number of the M non-orthogonal layers, where M is a positive integer;

The network device determines at least one complex symbol group corresponding to each non-orthogonal layer of the M non-orthogonal layers among the N complex symbols, where the mth non-orthogonal layer corresponds to s m complex numbers Symbol group,
The mth non-orthogonal layer is any one of the M non-orthogonal layers, m≤M, and m is a positive integer;

Determining, by the network device, a mapping rule corresponding to each of the N complex symbol groups according to a layer sequence number of the M non-orthogonal layers and a group identifier of each of the N complex symbol groups; wherein, The mapping rule corresponding to the sm complex symbol groups corresponding to the mth non-orthogonal layer is a group identifier corresponding to the sm complex symbol groups corresponding to the mth non-orthogonal layer, and the network device respectively The layer number of the mth non-orthogonal layer is determined.
The method according to any one of claims 7 to 10, wherein the network device determines a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, including:

Determining, by the network device, the hopping offset according to a pilot in the uplink signal;

Determining, by the network device, a mapping rule corresponding to each of the N complex symbol groups according to the hopping offset and a group identifier of each of the N complex symbol groups.
The method according to any one of claims 8 to 15, wherein the network device, before demodulating the N complex symbol groups according to mapping rules respectively corresponding to the N complex symbol groups, further includes:

The network device performs descrambling processing on the N complex symbol groups scrambled in the uplink signal to obtain the N complex symbol groups, and the scrambling sequence used in the de-scrambling process is And determining, according to the first parameter, the time domain resource sequence number, and the at least one parameter of the cell identifier.
The method according to any one of claims 8 to 15, wherein the network device, before demodulating the N complex symbol groups according to mapping rules respectively corresponding to the N complex symbol groups, further includes:

Decoding, by the network device, the N complex symbol groups that are interleaved in the uplink signal to obtain the N complex symbol groups, where the interleaving pattern used in the deinterleaving process is according to the Determined by at least one parameter of a parameter, the time domain resource sequence number, and the cell identifier.
A data modulation device, characterized in that the device comprises:

a processing unit, configured to divide the data to be sent into N bit groups, N≥2 and N is an integer;

Generating N complex symbol groups, wherein the i-th complex symbol group is processed by processing the i-th bit group by using a mapping rule corresponding to the i-th bit group, and mapping rules corresponding to the i-th bit group And determining, according to the group identifier and the first parameter of the i-th bit group, the first parameter includes a pilot parameter, a hopping identifier, a terminal device identifier, a layer sequence number of a non-orthogonal layer, and a hopping offset At least one of the mapping rules corresponding to the N bit groups respectively includes at least two mapping rules different from each other, 0≤i≤N-1 and i is an integer;

a sending unit, configured to send the N complex symbol groups.
The apparatus according to claim 18, wherein the mapping rule corresponding to the i-th bit group is determined according to the group identifier of the i-th bit group, the first parameter and the second parameter, The second parameter includes at least one of a cell identifier, a time domain resource sequence number, and a period P.
The apparatus according to claim 18 or 19, wherein when the data to be transmitted is repeatedly transmitted, the mapping rule corresponding to the N bit groups and the N bits at the time of the first transmission are transmitted each time The mapping rules corresponding to the group are the same.
The apparatus according to any one of claims 18 to 20, wherein the terminal device identifier is a radio network temporary identifier RNTI, or a radio resource control RRC identifier, or a temporary mobile subscriber identification number TMSI.
The device according to any one of claims 19 to 21, wherein the processing unit is further configured to:

Performing a scrambling process on the N complex symbol groups before transmitting the N complex symbol groups, wherein the scrambling sequence used in the scrambling process is based on the first parameter, the time domain resource Determining, by a sequence number, at least one parameter in the cell identifier;

The sending unit is specifically configured to:

Transmitting the signal of the N complex symbol groups after scrambling.
The device according to any one of claims 19 to 21, wherein the processing unit is further configured to:

Interleaving the N complex symbol groups before transmitting the N complex symbol groups, where the interleaving pattern used in the interleaving process is based on the first parameter, the time domain resource sequence, and the Determining at least one parameter in the cell identifier;

The sending unit is specifically configured to:

Transmitting the signal of the N complex symbol groups after interleaving.
A data demodulating device, characterized in that the device comprises:

a receiving unit, configured to receive an uplink signal;

a processing unit, configured to determine a mapping rule corresponding to each of the N complex symbol groups in the uplink signal, where N≥2 and N is an integer;

Demodulating a corresponding complex symbol group according to a mapping rule corresponding to each of the N complex symbol groups;

The mapping rule corresponding to the ith complex symbol group is determined according to the group identifier of the ith complex symbol group and the first parameter, where the first parameter includes a pilot parameter, a hopping identifier, and a terminal device. At least one of an identifier, a layer sequence number of the non-orthogonal layer, and a hopping offset; the mapping rule corresponding to the N complex symbol groups respectively includes at least two mapping rules different from each other, 0≤i≤N -1 and i is an integer.
The apparatus according to claim 24, wherein the mapping rule corresponding to the i-th complex symbol group is determined according to the group identifier of the i-th complex symbol group, the first parameter and the second parameter The second parameter includes at least one of a cell identifier, a time domain resource sequence number, and a period P.
The device according to claim 24 or 25, wherein the processing unit is further configured to:

Determining, when the N complex symbol groups are not the first transmission, determining a mapping rule corresponding to the N complex symbol groups and a mapping rule corresponding to the N complex symbol groups when the N complex symbol groups are first transmitted respectively the same.
The apparatus according to any one of claims 24 to 26, wherein the terminal device identifier is a radio network temporary identifier RNTI, or a radio resource control RRC identifier, or a temporary mobile subscriber identification number TMSI.
The device according to any one of claims 24 to 27, wherein the processing unit is specifically configured to:

Determining, according to the pilot in the uplink signal, a pilot parameter corresponding to the pilot;

Determining, according to the pilot parameter and a group identifier of each complex symbol group in the N complex symbol groups, mapping rules respectively corresponding to the N complex symbol groups.
The device according to any one of claims 24 to 27, wherein the processing unit is specifically configured to:

Determining the hopping identifier according to a pilot in the uplink signal;

Determining, according to the hopping identifier and the group identifier of each of the plurality of complex symbol groups of the N complex symbol groups, a mapping rule corresponding to the N complex symbol groups.
The device according to any one of claims 24 to 27, wherein the processing unit is specifically configured to:

Determining, according to the pilot in the uplink signal, the terminal device identifier;

Determining, according to the terminal device identifier and the group identifier of each of the plurality of complex symbol groups in the N complex symbol groups, a mapping rule corresponding to the N complex symbol groups.
The device according to any one of claims 24 to 27, wherein the processing unit is specifically configured to:

Determining the layer numbers of the M non-orthogonal layers, where M is a positive integer;

Determining at least one complex symbol group corresponding to each of the M non-orthogonal layers of the N complex symbols, wherein the mth non-orthogonal layer corresponds to sm complex symbol groups,
The mth non-orthogonal layer is any one of the M non-orthogonal layers, m≤M, and m is a positive integer;

Determining, according to a layer number of the M non-orthogonal layers and a group identifier of each of the plurality of complex symbol groups, a mapping rule corresponding to the N complex symbol groups; wherein, the mth The mapping rule corresponding to each of the s m complex symbol groups corresponding to the non-orthogonal layer is a group identifier corresponding to the sm complex symbol groups corresponding to the mth non-orthogonal layer, and the mth The layer number of the non-orthogonal layer is determined.
The device according to any one of claims 24 to 27, wherein the processing unit is specifically configured to:

Determining the hopping offset according to a pilot in the uplink signal;

Determining, according to the hopping offset and the group identifier of each complex symbol group in the N complex symbol groups, mapping rules respectively corresponding to the N complex symbol groups.
The device according to any one of claims 25 to 32, wherein the processing unit is further configured to:

Before demodulating the N complex symbol groups according to mapping rules corresponding to the N complex symbol groups respectively, performing descrambling processing on the N complex symbol groups scrambled in the uplink signal, And the scrambling sequence used in the de-scrambling process is determined according to at least one of the first parameter, the time domain resource sequence number, and the cell identifier.
The device according to any one of claims 25 to 32, wherein the processing unit is further configured to:

Before demodulating the N complex symbol groups according to mapping rules respectively corresponding to the N complex symbol groups, performing deinterleaving processing on the N complex symbol groups subjected to interleaving in the uplink signal, to obtain the The N complex symbol groups are determined according to at least one of the first parameter, the time domain resource sequence number, and the cell identifier.
A terminal device, comprising: a transceiver, a processor, and a memory: the memory is for storing a computer program; the processor calls a computer program stored by the memory, and is executed by the transceiver A method as claimed in any one of claims 1 to 6.
A network device, comprising: a transceiver, a processor, and a memory: the memory is for storing a computer program; the processor calls a computer program stored by the memory, and is executed by the transceiver A method as claimed in any one of claims 7 to 17.
A computer readable storage medium, characterized in that the computer readable storage medium stores a computer program that, when run on a computer, causes the computer to perform the method of any one of claims 1 to 17.
A computer program product comprising a program, wherein when the program is run on a computer, causing the computer to perform the method of any one of claims 1 to 17.